A triangle, you have seen, is a simple closed curve made of three line segments. It has three vertices, three sides, and three angles.
You know how to classify triangles based on the (i) sides (ii) angles.
(i) Based on Sides: Scalene, Isosceles, and Equilateral triangles.
(ii) Based on Angles: Acute-angled, Obtuse-angled, and Right-angled triangles.
The median of a Triangle
A triangle's altitude is the vertical distance from the corner to the opposite side of the shape. The height of a triangle also called its altitude, is a straight line drawn from the triangle's vertex to the opposite side, forming a right-angled triangle with the base.
1. Scalene Triangle: A scalene triangle is one in which all three sides are of different lengths. Scalene TriangleThe steps to derive the formula are as follows:
2. Isosceles Triangle: A isosceles triangle in which two sides are equal is called an isosceles triangle. The altitude of an isosceles triangle is perpendicular to its base.
Isosceles Triangle
3. Equilateral triangle: A triangle in which all three sides are equal is called an equilateral triangle.
Equilateral Triangle
Let us assume, the sides of the equilateral triangle to be 'a', its perimeter = 3a. Therefore, its semi-perimeter (s) = 3a/2 and the base of the triangle (b) = a.
4. Right Triangle: In a right triangle, one angle measures 90 degrees.
In this case, one altitude is the same as the side opposite the right angle (the hypotenuse), and the other two altitudes are the legs of the triangle. The orthocenter is at the right angle vertex.
Right Triangle
In the above figure, Let us see the derivation of the formula for the altitude of a right triangle.
△PSR ∼△RSQ
5. Obtuse Triangle: In an obtuse triangle, one angle measures more than 90 degrees.
In this case, one altitude lies outside the triangle, and the other two altitudes lie inside the triangle. The orthocenter is located outside the triangle.
Obtuse Triangle
Equilateral Triangle | h = (½) × √3 × s |
Isosceles Triangle | h =√(a2−b2/4) |
Right Triangle | h =√(xy) |
An exterior angle of a triangle is equal to the sum of its interior opposite angles.
To prove:
∠ACD = ∠A + ∠B
Exterior Angle of a Triangle
We will prove this using the alternate angles property.
Let's draw a line CE from C which is parallel to AB.
The exterior Angle of a Triangle shows the line CE II AB
A triangle is the smallest polygon that has three sides and three interior angles.
Theorem: The angle sum property of triangle states that the sum of interior angles of a triangle is 180°.
Proof: Consider an ∆ABC, as shown in the figure below.
Draw a line PQ parallel to the side BC of the given triangle.
Angle Sum Property of a TriangleSo, PQ is a straight line, it can be concluded that:
∠PAB + ∠BAC + ∠QAC = 180° ..(1)
Since PQ||BC and AB, AC are transversals,
Therefore,
∠QAC = ∠ACB (a pair of alternate angles)
Also, ∠PAB = ∠CBA (a pair of alternate angles)
Substituting the value of ∠QAC and ∠PAB in equation (1),
∠ACB + ∠BAC + ∠CBA= 180°
Note: The sum of the interior angles of a triangle is 180°.
An equilateral triangle is one in which all three sides are equal. It is a special case of the isosceles triangle where the third side is also equal. In the triangle XYZ, XY = YZ = ZX.
Equilateral Triangle
The properties of an equilateral triangle are:
An isosceles triangle is a triangle that comprises 2 equal sides, regardless of the direction of the apex of the triangle points.
Isosceles Triangle In the isosceles triangle ABC, AB = AC.
Some of its properties are:
According to this principle, the sum of the lengths of any two sides of a triangle must be greater than the length of the third side. This rule is known as the Triangle Inequality Theorem.
Mark three non-collinear spots A, B, and C in your playground
ΔABC
Now, start from A and reach C, walking along one or more of these paths.
She can, for example, walk first along AB and then along BC to reach C, or she can walk straight along AC.
She will naturally prefer the direct path AC. If she takes the other path (AB and then BC ), she will have to walk more.
In other words,
(i) AB + BC > AC
Similarly, if one were to start from B and go to A, he or she will not take the route BC and CA but will prefer BA This is because
(ii) BC + CA > AB
By a similar argument, you find that
(iii) CA + AB > BC
Note: This observation suggests that the sum of the lengths of any two sides of a triangle is greater than the third side.
Pythagoras, a Greek philosopher of the sixth century B.C. is said to have found a very important and useful property of right-angled triangles.
Pythagorean Theorem
Note: In a right-angled triangle, the sides have some special names. The side opposite to the right angle is called the hypotenuse; the other two sides are known as the legs of the right-angled triangle.
Pythagoras Theorem
Consider a right-angled triangle ABC, right-angled at B. Draw a perpendicular BD meeting AC at D.
Right Angled Triangle
In △ABD and △ACB,
∠A = ∠A (common)
∠ADB = ∠ABC (both are right angles)
Thus, △ABD ∼ △ACB (by AA similarity criterion)
Similarly, we can prove △BCD ∼ △ACB.
Thus △ABD ∼ △ACB,
Therefore, AD/AB = AB/AC.
We can say that AD × AC = AB2.
Similarly, △BCD ∼ △ACB.
Therefore, CD/BC = BC/AC. We can also say that CD × AC = BC2.
Adding these 2 equations,
we get AB2 + BC2 = (AD × AC) + (CD × AC)
AB2 + BC2 = AC(AD +DC)
AB2 + BC2 =AC2
Hence proved.
Example: Consider a right-angled triangle with sides of lengths 5, 12, and c units. We can check if the Pythagorean theorem holds true for this triangle:
Example of Pythagorean Theorem
Note:
- Since both the values are equal, the Pythagorean theorem holds true for this right-angled triangle.
- This theorem is an essential concept in mathematics and can be used to solve various problems involving right-angled triangles.
83 videos|156 docs|32 tests
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1. What is a triangle? |
2. What is the median of a triangle? |
3. What is the altitude of a triangle? |
4. What are the differences between median and altitude? |
5. What is the angle sum property of a triangle? |
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